Use of models in large-area forest surveys: comparing model-assisted, model-based and hybrid estimation

D I S C U S S I O N Open Access

Use of models in large-area forest surveys:

comparing model-assisted, model-based and hybrid estimation

Göran Ståhl¹, Svetlana Saarela^1* , Sebastian Schnell¹, Sören Holm¹, Johannes Breidenbach², Sean P. Healey³, Paul L. Patterson³, Steen Magnussen⁴, Erik Næsset⁵, Ronald E. McRoberts³and Timothy G. Gregoire⁶

Abstract

This paper focuses on the use of models for increasing the precision of estimators in large-area forest surveys. It is motivated by the increasing availability of remotely sensed data, which facilitates the development of models predicting the variables of interest in forest surveys. We present, review and compare three different estimation frameworks where models play a core role: model-assisted, model-based, and hybrid estimation. The first two are well known, whereas the third has only recently been introduced in forest surveys. Hybrid inference mixes design- based and model-based inference, since it relies on a probability sample of auxiliary data and a model predicting the target variable from the auxiliary data..We review studies on large-area forest surveys based on model-assisted, model- based, and hybrid estimation, and discuss advantages and disadvantages of the approaches. We conclude that no general recommendations can be made about whether model-assisted, model-based, or hybrid estimation should be preferred. The choice depends on the objective of the survey and the possibilities to acquire appropriate field and remotely sensed data. We also conclude that modelling approaches can only be successfully applied for estimating target variables such as growing stock volume or biomass, which are adequately related to commonly available remotely sensed data, and thus purely field based surveys remain important for several important forest parameters.

Keywords:Design-based inference, Model-assisted estimation, Model-based inference, Hybrid inference, National forest inventory, Remote sensing, Sampling

Introduction

Use of models in large-area surveys of forests is attracting increased interest. The reason is the improved availability of auxiliary data from various remote sensing platforms.

Aerial photographs (e.g.,Næsset 2002a, Bohlin et al. 2012) and optical satellite data (e.g.,Reese et al. 2002) have been available and used operationally for many decades, while data from profiling (e.g., Nelsonet al. 1984, Nelson et al.

1988) and scanning lasers (e.g., Næsset 1997) and radars (Solberg et al. 2010) have become available for practical applications more recently. Some of the new types of remotely sensed data, such as data from laser scanners, have already become widely applied in forest inventor- ies (e.g., Næsset 2002b). A common application involves

the development of models that are applied wall-to-wall over an area of interest (e.g.,Næsset 2004), often for pro- viding data for forest management. However, this type of data is increasingly applied also in connection with large- area forest surveys, such as national-level forest inventor- ies (Tomppo et al. 2010, Asner et al. 2012).

Applications of models in large-area forest surveys often use the model-assisted estimation framework (Särndal et al.

1992) where a model is used to support the estimation following probability sampling within the context of design-based inference (Gregoire 1998). Importantly, an inadequately specified model will not make the estimators biased in this case, but only affect the variance of the esti- mators. Examples of large-area forest inventory applica- tions include Andersen et al. (2011) who applied the technique in Alaska, Gregoire et al. (2011) and Gobakken et al. (2012), who applied it in Hedmark County, Norway, and Saarela et al. (2015a) who used it in Kuortane, Finland.

* Correspondence:svetlana.saarela@slu.se

1Department of Forest Resource Management, Swedish University of Agricultural Sciences, Umeå, Sweden

Full list of author information is available at the end of the article

© 2016 Ståhl et al.Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Some applications of models in large-area forest sur- veys involve model-based inference (Gregoire 1998), which to a larger extent than model-assisted estimation relies on model assumptions. In this case an inad- equately specified model might make the estimators both biased and imprecise. On the other hand, with accurate models this mode of inference can be very effi- cient (e.g., Magnussen 2015). Examples of applications in forest inventory include McRoberts (2006, 2010), who used model-based inference for estimating forest area based on Landsat data in northern Minnesota, U.S.A., Ståhl et al. (2011) who used it for estimating biomass in Hedmark, Norway, using laser data, and Healey et al.

(2012) who applied the technique in California, U.S.A., using data from the space-borne Geoscience Laser Altimeter System (GLAS).

Non-parametric modelling, applying methods such as the k-Nearest Neighbours (kNN) technique (Tomppo and Katila 1991, Tomppo et al. 2008), has a long trad- ition in forest inventories. These techniques typically have been applied for providing small-area estimates through combining field sample plots and various sources of remotely sensed data. However, the kNN technique has also been used in connection with model- assisted estimation (e.g., Baffetta et al. 2009, 2011, Mag- nussen and Tomppo 2015) and model-based inference (e.g.,McRoberts et al. 2007).

The objective of this paper was to present, review and discuss how models are applied in the case of model- assisted and model-based estimation in large-area forest surveys, and to discuss advantages and disadvantages of the two estimation frameworks in this context. We also present, review and discuss a newly introduced estima- tion framework where probability sampling is applied for the selection of auxiliary data, upon which model-based inference is applied in a second phase. This framework in denoted hybrid inference, after Corona et al. (2014).

We restrict the study to large-area estimation. This is the case of national forest inventories and greenhouse gas inventories under the United Nations Framework Con- vention on Climate Change (e.g., Tomppo et al. 2010).

Importantly, in this case there is no need to make assump- tions about residual error terms linked to individual popu- lation elements, which is a core issue in model-based small-area estimation (e.g.,Breidenbach and Astrup 2012, Breidenbach et al. 2015). The reason is that the residual error terms will have almost no influence on the results, as will be demonstrated below. However, we do not spe- cify how large a“large area”must be, but use the term as a general concept.

Below, we present the basics of model-assisted, model- based, and hybrid inference (chapter 2). Subsequently we present a brief review of the application of these methods in forest surveys (chapter 3), and, finally, we

discuss advantages and disadvantages of the different ap- proaches and make conclusions (chapters 4 and 5).

Basics of model-assisted, model-based and hybrid estimation

In this chapter we summarize some basic concepts related to the use of models in large-area forest surveys. We restrict the scope to cases where models are applied for improving estimators (or predictors) once sample or wall- to-wall data have been collected. However, models may also be used in the design phase for improving the sample selection (e.g.,Fattorini et al. 2009, Grafström et al. 2014), but such cases are not covered in this article.

Design-based inference

This paper requires a basic understanding of the concepts design-based and model-based inference (e.g.,Cassel et al.

1977, Särndal 1978, Gregoire 1998, McRoberts 2010).

Design-based inference typically assumes a finite population of elements to which one or more fixed target quantities are linked. The objective normally is to estimate some fixed population parameter, such as the total or the mean of these quantities (e.g., Gregoire and Valentine 2008). In order to estimate the fixed but un- known parameters a probability sample is selected from the population according to some appropriate sampling design, which assigns positive inclusion probabilities to each element. Mathematical formulas (estimators) are used for estimating the parameters based on the sample data. The estimates are random variables due to the ran- dom selection of samples, i.e., the estimators produce different values depending on which population ele- ments are included in the sample.

The Horvitz-Thompson estimator can be applied to any probability sampling design with inclusion probabil- ities known at least for the sampled units (e.g., Särndal et al. 1992). Using this estimator, a population total,τ, is estimated as

^ τ¼ X

i∈s

y_i

πi ð1Þ

Here,yi is the variable of interest for thei:th sampled element,πiis the inclusion probability, andsis the sample.

The precision of an estimator is usually expressed through its variance, which is a fixed quantity given the population, the design, and the estimator. The variance usually can be estimated through a variance estimator, and confidence intervals can be computed as a means to provide decision makers with the range of values wherein the true population parameter is located with a defined probability.

In case of the Horvitz-Thompson estimator, a general formula for the variance is

varð Þ ¼^τ X

i∈U

X

j∈U πij−πiπj

y_i πi

y_j

πj ð2Þ

In addition to the previously introduced notation,πijis the joint probability of inclusion for unit i and j. The step from the variance to a variance estimator and a confidence interval normally is straightforward (e.g., Gregoire and Valentine 2008).

Some key features of design-based inference are:

The values that are linked to the population elements are fixed

The population parameters about which we wish to infer information are also fixed

Our estimators of the parameters are random because a probability sample is selected according to some sampling design, such as simple random sampling

The probability of obtaining different samples can be deduced from the design and used for inference The foundations of design-based inference were laid out by Neyman (1934) and it is the standard mode of in- ference in most statistical surveys, including sample- based national forest inventories (Tomppo et al. 2010) that are carried out in a large number of countries.

Design-based inference through model-assisted estimation

Models can be used to improve estimators under the design-based framework. An important category of such estimators are known as model-assisted estimators (Särndal et al. 1992). The general form of such estima- tors, for estimating a population total, is

^

τma¼X

i∈U^y_iþ X

i∈s

y_i−^y_i

ð Þ

πi ð3Þ

where the first part of the estimator is a sum of model estimates of each element in the population; the second term is a Horvitz-Thompson estimator of the total of the deviations between observed values and values esti- mated by the model; the subscript‘ma’ is used to point out that the estimator is model-assisted. Thus, the model-assisted estimator can be seen as composed of a first crude estimator which is refined through a correc- tion term that makes it asymptotically unbiased when the model is external (in which case Eq. 3 is often re- ferred to as a difference estimator), and approximately unbiased when the model is internal (in which case Eq. 3 is often referred to as a generalised regression estimator). In case the model is external the variance is

varð^τmaÞ ¼X

i∈U

X

j∈U πij−πiπj

e_i πi

ej

πj ð4Þ This is almost the same expression as the variance in Eq. (2), but theyi- terms have been replaced byei=yi− ŷi. If an accurate model is used the latter terms should be much smaller than the former, and thus the variance of the model-assisted estimator should be much smaller than the variance of the ordinary Horvitz-Thompson es- timator, although this is not immediately clear when comparing Eq. 2 and Eq. 4.

Model-based inference

In contrast to design-based inference (including model- assisted estimators), a basic assumption underlying model-based inference is that the values that are linked to the elements in the population are realizations of ran- dom variables. As a consequence, target survey quan- tities such as population totals and means are also random variables. Thus, due to the different points of view underlying design-based and model-based inference some caution must be exercised when comparing results from the two inferential frameworks. For example, with model- based inference the random population total (or mean) may be predicted or (as in this study) the expected value of the population total may be estimated. For large population the difference between these two quantities, in relative terms, typically is minor although for small populations the relative difference may be substantial. However, just like design-based inference, model-based inference in many cases is a useful and straightforward approach for quantify- ing target features of a population (e.g., Chambers and Clark 2012). In forest inventories, examples of such cases are surveys of remote areas with poor road infrastructure and small-area estimation for forest management. In both cases the field sample sizes typically are small or acquired through non-probability sampling whereas remotely sensed data are available wall-to-wall.

A basic assumption of model-based inference is that the random values of the population elements follow some specific model, e.g., a model based on auxiliary data derived from remote sensing. Thus, in the standard case, auxiliary data are available for all population elements. A simple and fairly general example is the lin- ear model, i.e., (in matrix form)

Y¼ Xβþ ð5Þ

where Y is an N× 1 matrix of the target variable, X anN×pmatrix of auxiliary data,β is ap× 1 matrix of model parameters, and an N× 1 matrix of random variables that follow some joint probability distribution;

N is the population size; in a forest survey it might be the number of grid cells which tessellate the study area.

Our objective typically is to predict a random popula- tion quantity, e.g., the mean or the total, following the selection of a sample for estimating the model parame- ters. Regardless of how the sample is selected, the obser- vations are realizations of random variables due to the model assumptions. Once the model parameters are esti- mated, we can use the estimated model, Y^ ¼ X^β, for predicting the population quantities of interest based on the auxiliary data; in standard cases these are assumed available for all population elements. Introducing1as an N× 1 vector of“1”-entries, the random population total τ* =1′Y=1′Xβ+1′εmay be predicted as

^

τ¼ 1^′Y^ ð6Þ

Note the distinction in nomenclature betweenestimating a fixed but unknown value (a population parameter) and predicting a random variable (e.g., Särndal 1978, Gregoire 1998). Note also that some authors (Chambers and Clark 2012) present the model-based predictor as a sum of two terms: the sum of the values of the sampled elements and the sum of the predictions for the non-sampled elements.

The difference between such a predictor and Eq. (6) would, however, be very small in case a small sample is selected from a large population.

Turning to the mean square error of the predictor in Eq. (6) we need to acknowledge that uncertainty is introduced both by the estimation of the model pa- rameters and by the random residual terms linked to each population element. Since the residuals may often be spatially auto-correlated estimating the mean square error of the Eq. (6) predictor may be very complicated.

However, an important feature of large-area surveys is that the relative difference between τ^* and E (τ^*) typically is very small (e.g., Chambers and Clark 2012, p. 16). The relative difference is 1′ε/(1′Xβ+1′ε), which intuitively can be seen to tend to zero as N tends to infinity, since in the cases we focus on the Xiβ -terms are almost always positive and typically much larger (in absolute value) than the residual terms, which may be either negative or positive. Thus, instead of predicting τ^*, in large-area estimation we can estimate E (τ^*), which simplifies the model-based inference. The estimator will be identical to Eq. (6), i.e., Eð Þ ¼^τ 1^′Y^, but it is now an estimator rather than a predictor. The variance (due to the model) of this estimator is simpler to derive, since it does not involve any residual terms; thus uncertainty in this case is introduced only through the model parameter estimation.

The variance of the estimator of E (τ^*) is

varE½ ^τ

¼1^′Xcov ^β X^′1 ð7Þ

The matrix cov β^ is the variance-covariance matrix of the model parameter estimates. A variance estimator is obtained by inserting the estimated covariance matrix in Eq. (7).

Thus, some key features of model-based inference are:

The values linked to population elements are random variables

Since the individual values are random variables so is the population total or mean that we wish to predict

A model for the relationship between the target variable and one or more auxiliary variable(s) can adequately conform to the trend in Y.

Auxiliary data are commonly available for all population elements

After having selected a sample–that need not be random–for estimating the model parameters, we apply the fitted model for predicting the target population quantity or estimating the expected value of this quantity.

Hybrid inference: a special case of model-based inference Auxiliary data may not be available prior to a forest survey and they may be very expensive to collect for all units in a population, as required for standard applica- tion of model-based inference. In such cases a probabil- ity sample of auxiliary data can be acquired, based on which the population total or mean of the auxiliary variable is estimated following design-based inference. A model can still be specified and applied regarding the re- lationship between the study variable and the auxiliary variables, and thus model-based inference can be applied once the auxiliary variable totals (or means) have been estimated through design-based inference.

Thus, design-based principles are applied in a first phase and model-based principles in a second phase.

This approach was termed hybrid inference by Corona et al. (2014) and in the present paper we follow that ter- minology. In a previous study by Mandallaz (2013) it was called pseudo-synthetic estimation. In a study by Ståhl et al. (2011) it was simply called model-based in- ference, although later denotedmodel-dependentestima- tion by Gobakken et al. (2012). However, the term model-dependent estimation appears to have been first proposed by Hansen et al. (1978, 1983) to include all sampling strategies that depend on the correctness of a model; according to Hansen et al. (1978) “a model- dependent design consists of a sampling plan and esti- mators for which either the plan or the estimators, or both, are chosen because they have desirable properties

under an assumed model, and for which the validity of inferences about the population depends on the degree to which the population conforms to the assumed model.” Thus, standard model-based inference as well as hybrid inference, and other approaches, belong to Hansen’s model-dependent category.

In the case of hybrid inference, expected values and variances are derived by considering both the design through which auxiliary data were collected and the model used for predicting values of population elements based on the auxiliary data. Thus, assuming we use a linear model, a general estimator of E (τ^*) is given as

Eð Þ ¼^τ X

i∈s

Xiβ^

πi ¼π^′Xβ^ ð8Þ wheres is the sample of auxiliary data,πiis the prob- ability of including population elementiinto the auxiliary data sample, π is ann-length column vector of (1/πi) – values, andXis ann×pmatrix of sampled auxiliary data.

The model parameters are estimated from a sample that is assumed to be independent from the sample of auxiliary data.

In deriving the variance of the estimator in Eq. (8), note that the part π′Xof the estimator is a 1 ×pmatrix of design-unbiased estimators of population totals of auxiliary data, which we denote^τx. This matrix is multi- plied by the matrix of estimated model parameters, i.e., the result is a sum of estimated population totals of aux- iliary variables times the corresponding model parameter estimate, such as τ^Xj⋅^βj. In each term the two compo- nents are independent, but the estimators of the auxil- iary variable totals as well as the estimators of the parameters are typically correlated. Thus, the variance (due to the sample and the model) is

varE½ ^τ

¼varτ^xβ^

¼ β^′covð Þβ^τx

þ τxcov ^β τ^′_xþ T rcovð Þcov^τx β^

ð9Þ

where covð Þ^τx is the covariance matrix of the estima- tors of the auxiliary variable totals andcov β^ is the co- variance matrix of the model parameter estimators. The Tr-operator is the trace, i.e., the sum of the diagonal en- tries in the matrix. The diagonal entries incovð Þ^τx are of the kind presented in Eq. (2). The off-diagonal entries are computed in a similar fashion (Särndal et al. 1992).

The covariance matrix of the model parameter estima- tors normally, under ordinary least squares regression assumptions, is derived asσ²(X′X)⁻¹whereσ²is the re- sidual variance, given the regression model. In case of heteroskedastic residual variance, alternative estimators can be applied (e.g., Saarela et al. 2015b). We do not offer a proof of Eq. (9), but readers familiar with the

variance of a product of two independent random vari- ables (i.e., var(WZ) = E(W)²var(Z) + E(Z)²var(W) + var(W)var(Z)) can identify the similarity with Eq. (9).

Although it seems likely that hybrid type estimators have been applied outside forest inventories, we have not yet found any description of them in non-forest publications.

In Fig. 1 an overview of the “positions” of standard design-based estimation (without using models), model- assisted estimation, hybrid estimation, and model-based estimation is shown with regard to how much these esti- mation techniques rely on (i) the correctness of the model and (ii) the use of probability sampling.

A brief review of the use of models in large-area forest surveys

From the methods section it is clear that models can be used in several ways for improving the estimation of tar- get quantities in large-area forests surveys. Our review is separated into the following cases:

Use of models in the context of design-based inference through model-assisted estimation

Use of models in the context of model-based inference through model-based estimation

Use of models in the context of hybrid inference

Model-assisted estimation in large-area forest surveys Formal model-assisted estimators appear to be fairly re- cently introduced to large-area forest surveys, although standard regression estimators (i.e., a simple kind of model-assisted estimators) have been applied in forest surveys for a long time. An important example of the latter kind is the Swiss national forest inventory (Köhl and Brassel 2001) where air photo interpretation has been combined with field surveys for a long time and the Italian national forest inventory, where a three-phase sampling approach is applied (Fattorini et al. 2006).

An early model-assisted study was conducted by Breidt et al. (2005), who used spline models in estimat- ing population totals in a simulation study linked to sur- veys of forest health. Model-assisted estimation was found to perform well in the context of a two-phase sur- vey with multiple auxiliary variables.

Opsomer et al. (2007) used model-assisted estimation in a two-phase systematic sampling design, applying general- ized additive models linking ground measurements with auxiliary information from remote sensing. The study was an extension of the study by Breidt and Opsomer (2000), where univariate models and a single-phase sampling strategy were applied.

In Boudreau et al. (2008), model-assisted estimation was used for estimating biomass in Quebec, Canada, based on data from a laser profiler, GLAS satellite data,

and land cover maps based on data from Landsat-7 ETM+. The study demonstrated that GLAS data could improve large-scale monitoring of aboveground biomass at large spatial scales; however, the presented estimators were not denoted “model-assisted”. Nelson et al. (2009) built upon the study by Boudreau et al. (2008) and intro- duced some new, partly model-based, estimation tech- niques. Andersen et al. (2009) presented a study based on model-assisted estimation where the biomass of west- ern Kenai, Alaska, was estimated based on samples of field and laser scanner data.

In Gregoire et al. (2011) model-assisted estimation was used for estimating aboveground biomass in Hedmark County, Norway, using sample data from laser profilers and scanners. The study triggered the start of a series of studies where the model-assisted theory, developed by Särndal et al. (1992), was applied for large-scale forest surveys based on samples of laser scanner data. Næsset et al. (2011) applied and compared two sources of auxil- iary information, laser scanner data and interferometric synthetic aperture radar data for model-assisted estima- tion of biomass over a large boreal forest area in the Aurskog-Høland municipality in Norway and quantified to what extent the two types of auxiliary data improved the estimated precision. Gobakken et al. (2012) com- pared the performance of model-assisted estimation with model-based prediction of aboveground biomass in

Hedmark County, Norway using data from airborne laser scanning as auxiliary data. The two approaches were found to yield similar results. Nelson et al. (2012) conducted a similar study over the same area using data from a profiling rather than scanning airborne laser, while Næsset et al. (2013b) evaluated the precision of the two-stage model-assisted estimation conducted by Gobakken et al. (2012). The authors noted the sensitivity of variance estimators to unequal sample strip length and systematically selected strips. The latter issue was further pursued by Ene et al. (2012), who showed that the variance was often severely overestimated when estimators assuming simple random sampling were ap- plied in this context. Similar results were reported by Magnussen et al. (2014).

Strunk et al. (2012a, 2012b) investigated different as- pects of model-assisted estimation. For example, the au- thors found that the laser pulse density had almost no effect on the precision of model-assisted estimators of core parameters, such as basal area, volume, and biomass.

Saarela et al. (2015a) proposed to use probability- proportional-to-size sampling of laser scanning strips in a two-phase model-assisted sampling study where the total growing stock volume was estimated in a boreal forest area in Kuortane, Finland. It was also found that full cover of Landsat auxiliary information improved the

Fig. 1An overview of to what degree different estimation approaches rely on the correctness of a model and probability sampling

precision of estimators compared to using only sampled LiDAR strip data.

Massey et al. (2014) evaluated the performance of the model-assisted estimation technique in connection with the Swiss national forest inventory. The authors also ad- dressed several methodological issues and, among other things, evaluated the performance of non-parametric methods in connection with model-assisted estimation and the close connection between difference estimators and regression estimators.

As some of the first laser scanning campaigns carried out for inventory purposes at the turn of the millennium have been repeated in recent years, change estimation assisted by laser data have become an important re- search area. Bollandsås et al. (2013), Næsset et al.

(2013a, 2015), Skowronski et al. (2014), McRoberts et al.

(2015), and Magnussen et al. (2015) analysed different approaches to modelling of change in biomass, such as separate modelling of biomass at each point in time and then estimate the difference, direct modelling of change with different predictor variables, such as the variables at each time point or their differences, and longitudinal models. These modelling techniques have been com- bined with different design-based and model-based esti- mators to produce change estimates and confidence intervals. Sannier et al. (2014) investigated change esti- mation based on a series of maps, which provided the auxiliary data for model-assisted difference estimation. A comprehensive review and discussion of change estima- tion can be found in McRoberts et al. (2014, 2015).

Melville et al. (2015) evaluated three model-based and three design-based methods for assessing the number of stems using airborne laser scanning data. The authors reported that among the design-based estimators, the most precise estimates were achieved through stratification.

Stephens et al. (2012) applied double sampling regres- sion estimators in the design-based framework for esti- mating carbon stocks in New Zealand forests using laser data as auxiliary information.

Chirici et al. (2016) compared the performance of two types of airborne LiDAR-based metrics in estimating total aboveground biomass through model-assisted esti- mators. The study area was located in Molise Region in central Italy. Corona et al. (2015) dealt with the use of map data as auxiliary information in a similar context.

Model-based and hybrid inference in large-area forest surveys

McRoberts (2006, 2010) applied model-based inference for estimating forest area using Landsat data as auxiliary information and field plots data. The studies were per- formed in northern Minnesota, U.S.A. In the studies the expected value of the total forest area was estimated, as

a means to reduce the complexity of the variance estimators.

A large number of studies have applied model- based prediction for mapping forest attributes across large areas using remotely sensed auxiliary information.

Baccini et al. (2008) used moderate resolution imaging spectro-radiometer (MODIS) and GLAS for mapping aboveground biomass across tropical Africa. Armston et al. (2009) used Landsat-5 TM and Landsat-7 ETM+

sensors for prediction foliage projective cover across a large area in Queensland, Australia. Asner et al. (2010) applied model-based prediction for mapping the above- ground carbon stocks using satellite imaging, airborne LiDAR and field plots over 4.3 million ha of Peruvian Amazon. Helmer et al. (2010) used time series from 24 Landsat TM/ETM+ and Advance Land Imager (ALI) scenes for mapping forest attributes on the island of Eleuthera. These are only examples of a very large number of studies where wall-to-wall remotely sensed data have been applied for mapping and monitoring forest re- sources. However, a majority of these studies do not apply a formal model-based inferential framework. For example, in case the uncertainty of estimators is addressed, usually the strict model-based inference approach [Eq. (7)] is not applied but instead some other, often ad-hoc, method that does not correctly reflect the uncertainty of the estimator or predictor involved.

Saarela et al. (2015b) evaluated the effects of model form and sample size on the precision of model-based estimators in the study area Kuortane, Finland, and iden- tified minor to moderate differences in results when dif- ferent model forms were applied. In a simulation study, Magnussen (2015) demonstrated the usefulness of model-based inference for forest surveys and argued that this approach has several advantages over traditional design-based sampling. McRoberts et al. (2014a,b) assessed the effects of uncertainty in model predictions of individual tree volume model predictions on large- area volume estimates in the survey framework of hybrid inference.

As previously mentioned, Corona et al. (2014) pro- posed to use the term hybrid inference for the case where a probability sample of auxiliary data may be se- lected, on which model-based inference is applied; the study by Corona et al. mainly dealt with small-area esti- mation issues. Ståhl et al. (2011), Gobakken et al. (2012), Nelson et al. (2012) and Magnussen et al. (2014) used hybrid inference for estimating the forest resources in Hedmark county, Norway, based on combinations of laser scanner data, laser profiler data, and field data. In the study by Magnussen et al. two populations were sim- ulated using the data. Healey et al. (2012) applied the technique in California, using GLAS data. In a study of boreal forests in Canada, Margolis et al. (2015) likewise

used GLAS data, in combination with airborne laser data, to estimate aboveground biomass.

Geographical mismatches between remotely sensed data and field measurements may considerably affect the precision of estimators in large-area surveys. The effects of such errors in model-based and model-assisted esti- mation were evaluated by Saarela et al. (2016).

The findings from the brief literature review are sum- marized in Fig. 2.

Discussion

The review revealed that use of models in large-scale forest inventories is widespread, although statistically strict applications of model-assisted estimators, model- based inference, or hybrid inference are rather limited.

While the model-assisted estimation framework is attracting large interest, model-based inference and hy- brid inference are not applied as much. A large number of studies apply approaches that could be classified as model-based inference, although they do not pursue any strict uncertainty analyses. In this context there is room for substantial improvement regarding how mean square errors or variances are estimated.

An advantage of model-assisted estimation, as com- pared to model-based and hybrid inference, is that the unbiasedness of estimators of totals and means do not rely on the correctness of the model; the model is only applied for enhancing a design-based estimator (Särndal et al. 1992). Whereas there is a theoretical chance that a model-assisted estimator is worse (in terms of variance) than a strictly design-based estimator if the model is ex- tremely poor, a well specified model might substantially increase the precision of the model-assisted estimator compared to the strictly design-based estimator. This was shown by, e.g., Ene et al. (2012) and Saarela et al.

(2015a).

If well specified models are available model-based in- ference is definitely a competitive alternative to design- based inference through model-assisted estimation (McRoberts et al. 2014a, b, Magnussen 2015). It has ad- vantages since it does not rely on a probability sample from the target area. Such samples may sometimes not be feasible due to poor infrastructure conditions, re- stricted access to private land, or the presence of areas that are for some reason dangerous to visit in the field.

Further, in case a probability sample has been selected, based upon which models are developed and applied,

Auxiliary information available for the entire population

Auxiliary information available as probability sample

Model-assisted estimation (with

stratification)

Model-based estimation

Hybrid inference Model-assisted estimation

Examples:

Köhl (2011) Fattorini et al. (2006) Breidt et al. (2005) Opsomer et al. (2007) Andersen et al. (2009) Gregoire et al. (2011) Næssetet al. (2011) Gobakken et al. (2012) Nelson et al. (2012) Ene et al. (2012) Stephens et al. (2012) Næssetet al. (2013a,b, 2015) Bollandsås et al. (2013) Magnussen et al. (2014, 2015) Massey et al. (2014) McRoberts et al. (2014, 2015) Sannier et al. (2014) Skowronski et al. (2014) Melville et al. (2015) Saarela et al. (2015a) Chirici et al. (2016) Examples:

Breidt & Opsomer (2000) Boudreau et al. (2008) Corona et al. (2015)

Examples:

Ståhl et al. (2011) Gobakken et al. (2012) Nelson et al. (2012) Healey et al. (2012) Magnussen et al. (2014) Corona et al. (2014) Margolis et al. (2015) Saarela et al. (2015b) Examples:

McRoberts (2006, 2010) Baccini et al. (2008) Armston et al. (2009) Asner et al. (2010) Helmer et al. (2010) Magnussen (2015) Saarela et al. (2016)

Fig. 2Overview of studies on model-assisted, model-based and hybrid estimation

model-based inference and model-assisted estimation usually lead to similar total estimates. In case the condi- tion X_n

i∈s

y_i−^y_i ð Þ

πi ¼0 holds the estimated values will be identical. However, Saarela et al. (2016) showed that the model-based variance estimators are less prone to prob- lems with geolocation mismatches between field plots and remotely sensed auxiliary data.

Hybrid inference is a straightforward approach in cases where auxiliary data are not available wall-to-wall and such data are expensive to acquire. In such cases a sample of auxiliary data can be selected, upon which the auxiliary variable totals and means can be estimated and used to- gether with model predictions that link the auxiliary vari- ables with the target variable. The approach so far appears to have been applied only in a limited number of forest in- ventories, although implicitly it has been used for a long time in forest inventories where models (such as volume, biomass and growth models) have been applied based on data from forest plots (Ståhl et al. 2014).

Overall, the use of models relies on auxiliary data that are correlated with or otherwise related with the target variable. Considering the variables normally included in national forest inventories (Tomppo et al. 2010) it is likely that a large number of variables would be very difficult to model in terms of remotely sensed data. This might be the case for forest floor vegetation, soil properties, and several types of forest damage. Modelling approaches linked to such variables would probably not improve the precision of estimators. Thus, a large number of variables, such as site index, forest floor vegetation, soil type, etc., are likely to require probability field samples.

Conclusions

We conclude by noting that all three approaches stud- ied: model-assisted estimation, model-based inference, and hybrid inference, have advantages and disadvantages when applied in large-area forest surveys. A main advan- tage of model-assisted estimation is that unbiasedness of estimators does not rely on the suitability of the model, but the model only helps to improve the precision of an estimator known to be (approximately) unbiased.

Model-based and hybrid inference rely on the suitability of the model, but may have several advantages under conditions where access to field plots is difficult or ex- pensive. All three approaches rely on the possibility to develop accurate models, which is possible for several important forest variables (such as biomass), but not for all variables that are included in a normal national forest inventory.

Competing interests

The authors declare that they have no competing interests.

Authors’contributions

GS: Initiative and major contribution to writing and review. SvS: Major contribution to writing and review. SeS, SH, JB, SPH, PLP, SM, EN, REM, TGG:

Contribution to review and suggestions for improvement to preliminary versions of the manuscript. All authors read and approved the final manuscript.

Author details

1Department of Forest Resource Management, Swedish University of Agricultural Sciences, Umeå, Sweden.²Norwegian Institute for Bioeconomy Research, Ås, Norway.³USDA Forest Service, Washington, D.C., USA.

4Canadian Forest Service, Pacific Forestry Centre, British Columbia, Canada.

5Norwegian University of Life Sciences, Ås, Norway.⁶School of Forestry and Environmental Studies, Yale University, New Haven, CT, USA.

Received: 12 November 2015 Accepted: 17 February 2016

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